Litcius/Paper detail

Constant Speed Control of Slider-Crank Mechanisms: A Joint-Task Space Hybrid Control Approach

Juan Alejandro Flores-Campos, Adolfo Perrusquía, Luis Héctor Hernández-Gómez, Noe Gonzalez, Alejandra Armenta-Molina

2021IEEE Access21 citationsDOIOpen Access PDF

Abstract

In this paper, a constant speed control of slider-crank mechanisms for machine tools is proposed. A joint-task space hybrid controller based on a second-order sliding mode control and time-base generator was used to guarantee a constant speed trajectory tracking and a complete turn of the mechanism crank. A switching criterion was implemented in order to avoid the singularities located at the two extreme positions of the slider stroke. A trapezoidal speed profile with parabolic blends was designed directly over task space slider trajectory considering a constant cutting speed, the workpiece dimensions and the slider stroke length. Stability of the second-order sliding mode control was validated with the Lyapunov stability theory. Simulations were carried out to verify this approach.

Topics & Concepts

Control theory (sociology)SliderTrajectoryConstant (computer programming)Computer scienceController (irrigation)CrankSliding mode controlLyapunov functionLyapunov stabilityElectronic speed controlNonlinear systemEngineeringControl (management)PhysicsAstronomyArtificial intelligenceMotion (physics)Programming languageElectrical engineeringAgronomyMechanical engineeringBiologyQuantum mechanicsIterative Learning Control SystemsRobotic Mechanisms and DynamicsDynamics and Control of Mechanical Systems